|
| |
|
|
|
|
||||
| Home Help Feedback Subscriptions Archive Search Table of Contents | ||||
First published online December 14, 2007
Journal of Experimental Biology 211, 42-48 (2008)
Published by The Company of Biologists 2008
doi: 10.1242/jeb.011882
Differential actions of diuretic factors on the Malpighian tubules of Rhodnius prolixus
1 Department of Biology, York University, 4700 Keele Street, Toronto, Ontario,
Canada, M3J 1P3
2 Department of Biology, McMaster University, 1280 Main Street West, Hamilton,
Ontario, Canada, L8S 4K1
3 Department of Biology, University of Toronto at Mississauga, 3359 Mississauga
Road North, Mississauga, Ontario, Canada, L5L 1C6
* Author for correspondence (e-mail: adonini{at}yorku.ca)
Accepted 22 October 2007
 |
Summary |
|---|
 TOP Summary INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
|---|
9 mV)
lumen-positive shift in TEP of the upper tubule but had no effect on the rate
of fluid secretion or ion composition of the secreted fluid. In contrast to
5HT, both peptides failed to activate KCl reabsorption by the lower tubule.
Leucokinin I had no effect on the ion composition of fluid secreted by whole
or upper Malpighian tubules. We propose that: (1) 5HT and a native CRF-related
peptide similar to ZooneDH activate the same second messenger systems and ion
transporters in the upper tubule cells; (2) CRF-related peptide is utilized to
maintain high rates of fluid secretion during the post-feeding diuresis and is
additionally used at times when KCl reabsorption is unnecessary or
detrimental. The differential actions of multiple diuretic factors allows for
intricate control of ionic and osmotic balance in R. prolixus.
Key words: Rhodnius, diuretic hormone, Malpighian tubules, transepithelial potential, secreted fluid, CRF-related peptide, kinin, DH31
|
INTRODUCTION |
|---|
|
TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
|---|
;
Maddrell et al., 1991;
Maddrell, 1963). Both hormones
stimulate rapid fluid secretion by the upper secretory segment of the
Malpighian tubules (Maddrell,
1963; Maddrell et al.,
1991). Stimulation by 5HT produces a characteristic triphasic
change in transepithelial potential (TEP), corresponding to sequential
activation of an apical Cl– conductance (phase 1), an apical
V-type H+-ATPase (phase 2) and a basal
Na+–K+–2Cl– cotransporter
(phase 3) (O'Donnell and Maddrell,
1984; Ianowski and O'Donnell,
2001). The resulting movement of Na+, K+ and
Cl– from the hemolymph, across the tubule cells and into the
tubule lumen drives the flow of osmotically obliged water through
aquaporin-like channels (Echevarria et al.,
2001; Martini et al.,
2004). The actions of 5HT on the upper tubule are mediated by the
second messenger cyclic AMP (Maddrell et
al., 1971; Montoreano et al.,
1990; Martini et al.,
2004). Depletion of K+ from the hemolymph during this
rapid diuresis is prevented by KCl reabsorbtion by the tubule's lower segment,
through processes that are also stimulated by 5HT
(Maddrell, 1978;
Maddrell et al., 1993;
Haley and O'Donnell, 1997).
The effect of the peptidergic DH on the fluid secretion rates of upper tubules
is similar to that of 5HT, but studies on the exact mechanisms of its actions
have been hindered because the hormone has yet to be identified.
A number of peptides with diuretic effects have been discovered in other
insects. These peptides belong to one of at least three families of peptides;
the corticotropin-releasing factor (CRF)-related DHs, the calcitonin
(CT)-related DHs and the kinin-related DHs. The CRF- and CT-related DHs act
through cyclic AMP in tubules of several species to activate various
transporters like the V-type H+-ATPase, Na+ channels and
the Na+–K+–2Cl–
cotransporter (Plawner et al.,
1991; Coast et al.,
2005; Coast et al.,
2002; Cabrero et al.,
2002; Coast et al.,
2001). The kinin-related DHs generally act through an increase in
intracellular Ca2+ levels to activate Cl–
conductance pathways (O'Donnell et al.,
1998; Beyenbach,
2003). The presence and release into the hemolymph of CRF-related,
CT-related and kinin-related peptides in R. prolixus have been
suggested on the basis of immunohistochemical, radioimmunological and high
performance liquid chromatographic techniques
(Te Brugge et al., 1999;
Te Brugge and Orchard, 2002;
Te Brugge et al., 2005). The
exogenous CRF-related peptides ZooneDH and DippuDH46 from
Zootermopsis nevadensis and Diploptera punctata,
respectively, stimulate fluid secretion and increase the cyclic AMP content of
the upper tubules of R. prolixus
(Te Brugge et al., 2002). The
CRF-related peptides are potent stimulators of fluid secretion, capable of
eliciting maximal rates of secretion comparable to those of 5HT-stimulated
tubules (Te Brugge et al.,
2002). In contrast, the CT-related peptide DippuDH31
produces only small increases in secretion rates of R. prolixus upper
tubules, equivalent to 1.5% of maximal rates achieved with 5HT
(Te Brugge et al., 2005).
Interestingly, the CT-related peptide of R. prolixus has an identical
sequence to that of DippuDH31 and is herein referred to as
RhoprDH31 (Te Brugge et al., in
press). The non-native kinin-related peptides leucokinin I,
leucokinin VIII and locustakinin all fail to increase the rate of fluid
secretion in R. prolixus tubules
(Te Brugge et al., 2002).
To date, no studies have been performed on the effects of CRF-related, CT-related and kinin-related peptides on TEP or the ion composition of the fluid secreted by the upper tubules. Furthermore, it is not known whether these factors activate KCl reabsorption by the lower tubule. The present study reports the K+, Na+ and Cl– concentrations of the secreted fluid from upper tubules before and after treatment with 5HT, ZooneDH, RhoprDH31 and leucokinin I. The results demonstrate that the actions of ZooneDH on the upper tubules are similar to those of 5HT. In addition, none of the peptides were capable of activating KCl reabsorption by the lower tubule.
|
MATERIALS AND METHODS |
|---|
|
TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
|---|
20°C).
Upper Malpighian tubule secretion assay
Insects were dissected under saline that contained (mmol
l–1): 129 NaCl, 8.6 KCl, 10.2 NaHCO3, 4.3
NaH2PO4, 8.5 MgCl2, 2 CaCl2, 8.6
Hepes and 20 glucose at pH 7. Fine glass probes were used to dissect
individual whole Malpighian tubules from the insects and the tubules were cut
at the junction of the upper and lower segments. Individual upper segments of
the tubules were transferred into 90 µl droplets of saline in a
Sylgard-lined dish held under water-saturated paraffin oil. The open end of
each tubule was pulled out of the saline droplet and wrapped around a minuten
pin stuck into the Sylgard. Tubules were initially stimulated by adding a
final concentration of 25 nmol l–1 5HT to the saline droplets
since unstimulated tubules secrete at very low rates of about 0.1 nl
min–1. ZooneDH, RhoprDH31 and leucokinin I were
subsequently added to the saline droplet at the final concentrations noted in
the Results. Either for comparison purposes or to serve as a positive control,
tubules in some experiments were treated with 1 µmol l–1
5HT. Droplets of secreted fluid that formed at the pin were collected at
intervals using fine glass probes. Fluid secretion rates were determined by
measuring the diameter of the secreted fluid droplets with an ocular
micrometer, calculating their volumes as (
d3)/6, where
d is the diameter, and dividing the volume by the time over which the
droplets formed. The Na+, K+ and Cl–
concentrations of secreted fluid droplets were measured using ion-selective
microelectrodes, as described below.
Whole Malpighian tubule secretion assay
The procedure for the dissection of whole tubules was the same as that
described for the upper Malpighian tubules with the exception that the
terminal ampulla was included and the tubules were not cut at the junction of
the upper and lower segments. Whole tubules were transferred to saline
droplets held under water-saturated paraffin oil. Each tubule was arranged
such that the upper segment was held in a 90 µl droplet of saline modified
to contain 24 mmol l–1 KCl and 113.6 mmol
l–1 NaCl (all other solutes unaltered) and the lower segment
was held in a separate 90 µl droplet of saline containing 4 mmol
l–1 KCl and 133.6 mmol l–1 NaCl. This
approach has been shown to maintain high rates of fluid and K+
secretion by the upper tubule and high rates of KCl reabsorption by the lower
tubule (Haley and O'Donnell,
1997; Maddrell et al.,
1993). The junction of the upper and lower segments was positioned
in the paraffin oil between the two saline droplets. The ampulla was pulled
out of the droplet holding the lower segment of the tubule and wrapped around
a minuten pin. The upper segments of the tubules were stimulated by 1 µmol
l–1 5HT. Droplets of secreted fluid that had passed through
the lower segment and emerged at the ampulla were collected for 10–15
min. This was followed by the addition of 1 µmol l–1
ZooneDH, 0.1 µmol l–1 RhoprDH31 or 0.1 µmol
l–1 leucokinin I, the same concentrations of all three
peptides at once, or 1 mmol l–1 8-bromo-cyclic AMP to the
saline droplet containing the lower segment of the tubule, and collection of
fluid for a further 20–30 min. 5HT (1 µmol l–1) was
then added to the droplet bathing the lower tubule and fluid was collected for
10–30 min. Lastly, the tubule was cut at the junction between the upper
and lower segments and fluid emerging from the upper segment was collected.
Ion concentrations in the collected droplets were measured using ion-selective
microelectrodes.
Measurement of the transepithelial potential of upper Malpighian tubules
A previous study has validated the use of the Ramsay technique for the
measurement of TEP in upper Malpighian tubules of R. prolixus
(Ianowski and O'Donnell,
2001). Isolated upper tubules from 5th instars were transferred to
saline droplets under paraffin oil. The cut end of the tubule was pulled out
of the droplet and wrapped around a minuten pin. A fine glass probe was used
to make a small hole in the tubule wall between the saline droplet and the
minuten pin. The tip of a microelectrode filled with 3 mol
l–1 KCl was placed in the secreted fluid that emerged from
the hole in the tubule while a second, similar microelectrode was placed in
the saline droplet. The electrodes were connected through a high impedance
(1013 
) ML165 pH Amp to a Powerlab 4/30 data acquisition
system (ADInstruments, Colorado Springs, CO, USA). ZooneDH (1 µmol
l–1) or RhoprDH31 (0.1 µmol
l–1) was added to the saline droplet while recording the
transepithelial potential.
Construction of ion-selective microelectrodes
Microelectrodes were fabricated as described previously
(Rheault and O'Donnell, 2001;
Donini and O'Donnell, 2005).
The following ionophore cocktails and backfill solutions (in parentheses) were
used: Na+ ionophore II cocktail A (500 mmol l–1
NaCl), K+ ionophore I cocktail B (500 mmol l–1
KCl). The tips of these electrodes were dipped in a solution of
polyvinylchloride (PVC, Fluka, Buchs, Switzerland) in tetrahydrofuran (THF,
Fluka) to permit their use in fluid droplets under paraffin oil (see
Rheault and O'Donnell, 2004).
For the measurement of Cl–, a solid state silver/silver
chloride microelectrode was employed as previously described
(Donini and O'Donnell, 2005).
The microelectrodes were calibrated in the following solutions:
Na+, 15 mmol l–1 NaCl/135 mmol –1
LiCl and 150 mmol l–1 NaCl; K+, 15 mmol
l–1 KCl/135 mmol l–1 NaCl and 150 mmol
l–1 KCl; Cl–, 20 mmol l–1
KCl and 200 mmol l–1 KCl. Slopes for the electrodes [mean
± s.e.m. (N)] for a tenfold change in ion concentration were
53.9±1.4 mV (9) for Na+, 55.1±0.5 mV (26) for
K+ and 58.2±2 mV (9) for Cl–. The reference
microelectrode was filled with a solution of 500 mmol l–1
KCl. Electrodes were connected to a data acquisition system as described for
the measurement of transepithelial potential. The ion concentration of the
secreted fluid was calculated using the following formula:
[ion]sf=Cx10(
V/slope),
where [ion]sf is the ion concentration in the secreted fluid
droplet; C is the ion concentration in one of the calibration
solutions used to calibrate the electrodes; V is the voltage
difference between the droplet of secreted fluid and the same calibration
solution; and the slope is the change in voltage measured by the electrode in
response to a tenfold change in ion concentration. K+ interferes
with the response of the Na+ electrode, and the Na+
concentrations were therefore corrected using the Nicolsky–Eisenman
equation (Ammann, 1986) and a
selectivity coefficient (KNaK) of 100.32.
Although ion-selective microelectrodes measure ion activity and not
concentration, data can be expressed in terms of concentration if it is
assumed that the ion activity coefficient is the same in calibration and
experimental solutions.
|
|
RESULTS |
|---|
|
TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
|---|
;
Maddrell et al., 1991;
Ianowski and O'Donnell, 2001).
Fluid secreted by unstimulated upper tubules is K+ rich, whereas
that secreted by 5HT-stimulated tubules contains approximately equal
concentrations of Na+ and K+
(Maddrell and Overton, 1988).
Equimolar amounts of Na+ and K+ were evident when the
upper tubules were partially stimulated by a low concentration (25 nmol
l–1) of 5HT, and secreting at rates of approximately 5 nl
min–1, equivalent to 15% of the maximal rate
(Fig. 1A–C). For tubules
that subsequently received (1 µmol l–1) 5HT or ZooneDH the
[K+]/[Na+] ratios in response to 25 nmol
l–1 5HT were [mean ± s.e.m. (N)]
0.83±0.14 (6) and 1.03±0.15 (7), respectively. Addition of 5HT (1 µmol l–1) produced a rapid increase in the rate of fluid secretion, which peaked within 15 min (Fig. 1A). ZooneDH (1 µmol l–1) produced a similar increase in the rate of fluid secretion, although the response was slower, peaking at 25 min after applying ZooneDH.
Both 5HT and ZooneDH (1 µmol l–1) caused an increase in the Na+ concentration of the secreted fluid at the expense of K+ over time (Fig. 1B,C). The Na+ and K+ concentration of the secreted fluid changed by approximately 20–30 mmol l–1. The [K+]/[Na+] ratios 55 min after the addition of 1 µmol l–1 5HT or ZooneDH were 0.41±0.03 and 0.44±0.04, respectively. These values are significantly lower than those in response to 25 nmol l–1 5HT alone (Student's t-test, P=0.003 and P=0.001 for 5HT and ZooneDH, respectively). Neither 5HT nor ZooneDH had significant effects on the Cl– concentration of the secreted fluid over time (Fig. 1D).
R. prolixus upper tubules are sensitive to changes in the bath
concentration of K+, responding to a decrease in K+ bath
concentration with a decrease in the overall secretion of K+
(Maddrell et al., 1993).
However, our results do not reflect K+ depletion of the bathing
saline resulting from the high rates of ion transport by the tubules. The
final [K+] in the bathing droplet at the end of the experiments
(9.78±0.7 mmol l–1) was not different from that at the
beginning (8.45±0.3 mmol l–1) for tubules stimulated
with 5HT. Corresponding values for tubules stimulated with ZooneDH were
8.1±0.6 and 9.1±0.2 mmol l–1, respectively.
A high concentration (0.1 µmol l–1) of
RhoprDH31 alone increases fluid secretion by upper tubules to 1.5%
of the maximal value seen in response to 1 µmol l–1 5HT
(Te Brugge et al., 2005).
There is no effect of leucokinin I (0.1 µmol l–1) on fluid
secretion rate (Te Brugge et al.,
2005). In the presence of a low concentration of 5HT (25 nmol
l–1), neither RhoprDH31 nor leucokinin I (0.1
µmol l–1) altered fluid secretion rate or the composition
of the secreted fluid (Fig. 2).
These tubules secreted at high rates upon the addition of 1 µmol
l–1 5HT over the final 15 min of the experiment and without
altering the [K+]/[Na+] ratio.
|
; Ianowski
and O'Donnell, 2001) and consists of a characteristic triphasic
response. Unstimulated tubules have a lumen-negative TEP and application of a
high concentration of ZooneDH caused the TEP to change in three phases,
similar to the 5HT response (Fig.
3). The initial phase occurred within 1 min of ZooneDH application
and was characterized by a negative deflection of the TEP from a value of
–24.6±6.2 mV to –29.2±6.1 mV (N=5). Phase 2
peaked within 5 min of ZooneDH application and caused a large positive
deflection of the TEP to a value of +20.2±8 mV. In phase 3, the TEP
returned to a value of –19.1±8.9 mV, which was similar to but
more positive than the value in unstimulated tubules.
|
A high concentration of RhoprDH31 resulted in a positive deflection of the TEP from the unstimulated value of –34.8±3.8 mV to –25±3.4 mV (N=5), which stabilized within 5 min. These tubules subsequently responded to a high concentration of 5HT in the characteristic triphasic manner with phase 1 consisting of a slight (2 mV) negative deflection, phase 2 a large (60 mV) positive deflection and phase 3 returning to –15±5.3 mV, almost 20 mV more positive than the TEP prior to the addition of 5HT.
|
). The K+ concentration of the secreted fluid
collected from whole tubules was unaffected by ZooneDH, RhoprDH31
or leucokinin I applied individually (Fig.
4A–C) or in unison (Fig.
4E). We also examined the Cl– concentration of
the fluid secreted by whole tubules in response to leucokinin I because of the
effects of this peptide on Cl– conductance in tubules of
other species. Leucokinin I had no effect on the Cl–
concentration (Fig. 4D). In all
cases, the tubules were capable of reabsorbing K+ as seen by the
response to 5HT near the end of each experiment
(Fig. 4). Since 5HT is known to
act through the second messenger cyclic AMP in the upper tubule, we assessed
the effects of the membrane-permeable and phosphodiesterase-resistant cyclic
AMP analog 8-bromo-cyclic AMP on the lower tubule. There was a partial
stimulation of K+ reabsorption as seen by the decrease in
K+ concentration of the fluid secreted by whole tubules
(Fig. 4F). |
DISCUSSION |
|---|
|
TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
|---|
; Coast, 1997).
Upon application of ZooneDH to upper segments of the tubules and in the
presence of a low concentration of 5HT, the Na+ concentration of
the secreted fluid increased at the expense of K+. This effect was
similar to the effect of a high concentration of 5HT on the tubules. In both
cases the [K+]/[Na+] ratio was significantly reduced
over time. The resulting K+ and Na+ concentrations of
the secreted fluid collected 55 min after application of 1 µmol
l–1 5HT were 52±3 and 132±5.8 mmol
l–1, respectively. The K+ concentration is
slightly lower than the 70 mmol l–1 previously reported by
Maddrell and Phillips (Maddrell and
Phillips, 1975), whereas the Na+ concentration is
similar to the value of 125 mmol l–1 reported in the same
study. The apparent natriuretic activity of ZooneDH is consistent with another
CRF-related and native peptide, Achdo-DH, in the cricket
(Coast et al., 2002); however,
another CRF-related peptide in the mosquito, Anoga-DH44, does not
possess natriuretic activity (Coast et al.,
2005). All these peptides, as well as 5HT in R. prolixus,
appear to act through cyclic AMP.
Detailed comparison of the changes in transepithelial potential in response
to ZooneDH and 5HT reveals that the magnitude and timing of each of the three
phases is approximately the same. Pharmacological studies have attributed each
phase of the 5HT response to a specific ion-transport mechanism in the apical
or basal membranes of the upper tubule cells
(Ianowski and O'Donnell,
2001). It therefore seems likely that ZooneDH affects the same ion
transporters as 5HT. Our results, coupled with previous findings that ZooneDH
and 5HT both increase intracellular cyclic AMP levels (see
Te Brugge et al., 1999;
Te Brugge et al., 2002) in the
upper tubule cells, strongly suggest that a native CRF-related peptide and 5HT
in R. prolixus activate the same second messenger pathways and
ion-transport mechanisms in the upper tubule cells.
In our studies, the native CT-related peptide RhoprDH31 had no
significant effect on the rate of fluid secretion or the ion composition of
the secreted fluid when it was applied in the presence of 25 nmol
l–1 5HT. Previous reports showed a significant increase in
the rate of fluid secretion when the peptide (referred to then as
Dippu-DH31) was applied alone; however, the maximal rates achieved
were only 1.5% of those obtained with a high concentration of 5HT, and
the actions of the peptide were highly variable
(Te Brugge et al., 2005).
Given the small lumen-positive change in TEP in response to
RhoprDH31, the peptide may stimulate the V-type
H+-ATPase on the apical membrane (i.e. phase 2 of the response to
5HT or ZooneDH). If this is the case, then it would seem that the effects of
RhoprDH31 on the proton pump are relatively small (when compared
with ZooneDH or 5HT). Co-localisation of 5HT and RhoprDH31-like
material is found in cell bodies and their neurohemal sites on the abdominal
nerves, suggesting that these two factors may be co-released
(Te Brugge et al., 2005). When
1 µmol l–1 5HT is applied in the presence of
RhoprDH31, phase 1 of the 5HT response, which is proposed to
correspond to activation of an apical Cl– conductance, is
reduced [2 mV shift, see Fig.
3, and 10 mV shift with 5HT alone (see
Ianowski and O'Donnell,
2001)]. This pattern may reflect partial stimulation of proton
pump activity by RhoprDH31 and a consequent lumen-positive shift in
TEP, so that the lumen-negative shift produced by the increase in
Cl– conductance during phase 1 of the 5HT response is
reduced. Phase 2 of the 5HT response is no different in the presence of
RhoprDH31 (60 mV shift from phase 1), which is consistent with
a maximal stimulation of the proton pump. Phase 3 of the 5HT response,
corresponding to the subsequent activation of the basal
Na+–K+–2Cl– cotransporter,
in the presence of RhoprDH31 resulted in a TEP which was 20 mV
more positive than the TEP prior to the addition of 5HT. In contrast, 5HT
alone results in a phase 3 TEP, which is only 10 mV more positive than
the resting TEP (see Ianowski and
O'Donnell, 2001) (Fig.
2A). This result is also consistent with a continued potentiation
of proton pump activity by RhoprDH31.
In contrast to the secretory nature of the upper tubules, the lowermost
segments of the tubules are responsible for the reabsorption of KCl
(Maddrell and Phillips, 1975).
Reabsorption is activated by 5HT and the cells of the lower tubules respond
more rapidly to 5HT than those of the upper tubule
(Maddrell et al., 1993). This
is a particularly important physiological role since the high rate of KCl
transport from hemolymph to lumen by the upper tubules would quickly deplete
the hemolymph of K+ without reabsorption of K+
downstream. Our results demonstrate that ZooneDH and RhoprDH31
cannot activate KCl reabsorption by the lower tubules. Interestingly, Maddrell
(Maddrell, 1976) suggested
that different regions of the tubule are not controlled by a single hormone
since extracts of lateral neurosecretory cells of the mesothoracic ganglionic
mass stimulated secretion from the upper tubules but did not stimulate KCl
reabsorption from the lower tubule. The membrane-permeable and
phosphodiesterase-resistant cyclic AMP analog 8-bromo-cyclic AMP at least
partially activates K+ reabsorption, suggesting that cyclic AMP may
act as a second messenger for activation of one or more of the KCl
transporters in the lower tubule. Moreover, since 5HT, CRF-related and
CT-related peptides all appear to make use of cyclic AMP as a second
messenger, our results suggest that the cells of the lower tubules may not
express receptors for CRF-related and CT-related peptides.
Leucokinin I had no measurable effect on the Malpighian tubules of R.
prolixus. Te Brugge et al. (Te Brugge
et al., 2002) tested for effects of a number of kinin-like
peptides on the upper tubules of R. prolixus, revealing that none of
these peptides affected the rate of fluid secretion. Based on our results,
these findings can be extended to include no effect on the ion composition of
the secreted fluid or on the lower tubule. In addition, application of all
three peptides at once to the lower tubule had no effect on K+
concentration of the secreted fluid from whole tubules.
In summary, this study demonstrates that various putative diuretic factors
have different actions on the Malpighian tubules of R. prolixus.
Although CRF-related factors and 5HT have similar, if not identical, actions
on the upper tubules, an important difference is that CRF-related factors
cannot activate KCl reabsorption by the lower tubule. The native CT-related
factor RhoprDH31 has minimal and variable effects on fluid
secretion (Te Brugge et al.,
2005) and produces a small (9 mV) increase in the TEP of
upper tubules. Although our findings suggest that kinin-like factors do not
act on upper or lower Malpighian tubules of R. prolixus, kinins may
still be important in the post-feeding diuresis by acting on other relevant
tissues such as the crop and hindgut (see
Te Brugge et al., 2002).
It thus appears that R. prolixus has multiple signaling mechanisms
that permit complex control of hemolymph ionic and osmotic balance. During the
post-feeding diuresis, we propose that the quick and timely release of 5HT
(see Lange et al., 1989)
serves to activate KCl reabsorption by the lower tubule and rapid fluid
secretion by the upper tubule, which may be potentiated by the co-release of
RhoprDH31 (see Maddrell et al.,
1993; Te Brugge et al.,
2005). When hemolymph titers of 5HT fall to levels that are
insufficient to maintain high rates of fluid secretion by the upper tubules,
release of a native CRF-related peptide can be utilized to maintain these high
rates of secretion. In addition there are likely to be other times when
stimulation of upper tubule ion transport is needed without reabsorption of
KCl by the lower tubule. For instance, digestion of the red blood cells from
the bloodmeal may lead to a K+ load, which the insect needs to
eliminate. In this case the CRF-related peptide may be released in the absence
of 5HT.
|
References |
|---|
|
TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
|---|
Ammann, D. (1986). Ion-selective Microelectrodes – Principles, Design and Application. Berlin: Springer-Verlag.
Beyenbach, K. W. (2003). Regulation of tight junction permeability with switch-like speed. Curr. Opin. Nephrol. Hypertens. 12,543 -550.[Medline]
Cabrero, P., Radford, J. C., Broderick, K. E., Costes, L.,
Veenstra, J. A., Spana, E. P., Davies, S. A. and Dow, J. A. T.
(2002). The Dh gene of Drosophila melanogaster
encodes a diuretic peptide that acts through cyclic AMP. J. Exp.
Biol. 205,3799
-3807.
Coast, G. M. (1997). Neuropeptides implicated in the control of diuresis in insects. Peptides 17,327 -336.
Coast, G. M., Webster, S. G., Schegg, K. M., Tobe, S. S. and Schooley, D. A. (2001). The Drosophila melanogaster homologue of an insect calcitonin-like diuretic peptide stimulates V-ATPase activity in fruit fly Malpighian tubules. J. Exp. Biol. 204,1795 -1804.[Abstract]
Coast, G. M., Orchard, I., Phillips, J. E. and Schooley, D. A. (2002). Insect diuretic and antidiuretic hormones. In Advances in Insect Physiology. Vol.29 (ed. P. D. Evans), pp.279 -409. London: Academic Press.[CrossRef]
Coast, G. M., Garside, C. S., Webster, S. G., Schegg, K. M. and
Schooley, D. A. (2005). Mosquito natriuretic peptide
identified as a calcitonin-like diuretic hormone in Anopheles gambiae
(Giles), J. Exp. Biol.
208,3281
-3291.
Donini, A. and O'Donnell, M. J. (2005).
Analysis of Na+, Cl-, K+, H+ and
NH4+ concentration gradients adjacent to the surface of
anal papillae of the mosquito Aedes aegypti: application of
self-referencing ion selective microelectrodes. J. Exp.
Biol. 208,603
-610.
Echevarria, M., Ramirez-Lorca, R., Hernández, C. S., Gutiérrez, A., Méndez-Ferrer, S., González, E., Toledo-Aral, J. J., Ilundáin, A. A. and Whittembury, G. (2001). Identification of a new water channel (Rp-MIP) in the Malpighian tubules of the insect Rhodnius prolixus. Pflugers Arch. 442,27 -34.[CrossRef][Medline]
Haley, C. A. and O'Donnell, M. J. (1997). Potassium reabsorption by the lower Malpighian tubule of Rhodnius prolixus: Inhibition by Ba2+ and blockers of H+/K+-ATPases. J. Exp. Biol. 200,139 -147.[Abstract]
Ianowski, J. P. and O'Donnell, M. J. (2001). Transepithelial potential in Malpighian tubules of Rhodnius prolixus: lumen negative voltages and the triphasic response to serotonin. J. Insect Physiol. 47,411 -421.[CrossRef][Medline]
Lange, A. B., Orchard, I. and Barrett, F. M. (1989). Changes in haemolymph serotonin levels associated with feeding in the blood-sucking bug, Rhodnius prolixus. J. Insect Physiol. 35,393 -399.[CrossRef]
Maddrell, S. H. P. (1963). Excretion in the blood sucking bug, Rhodnius prolixus Stal. I. The control of diuresis. J. Exp. Biol. 40,247 -256.[Abstract]
Maddrell, S. H. P. (1976). Functional design of the neurosecretory system controlling diuresis. Am. Zool. 16,131 -139.
Maddrell, S. H. P. (1978). Physiological
discontinuity in an epithelium with an apparently uniform structure.
J. Exp. Biol. 75,133
-145.
Maddrell, S. H. P. and Overton, J. A. (1988).
Stimulation of sodium transport and fluid secretion by ouabain in an insect
Malpighian tubule. J. Exp. Biol.
137,265
-276.
Maddrell, S. H. P. and Phillips, J. E. (1975).
Secretion of hypo-osmotic fluid by the lower Malpighian tubules of
Rhodnius prolixus. J. Exp. Biol.
62,671
-683.
Maddrell, S. H. P., Pilcher, D. E. M. and Gardiner, B. O. C.
(1971). Pharmacology of the Malpighian tubules of
Rhodnius and Carausius: the structure-activity relationship
of tryptamine analogues and the role of cAMP. J. Exp.
Biol. 54,779
-804.
Maddrell, S. H. P., Herman, W. S., Mooney, R. L. and Overton, J.
A. (1991). 5-hydroxytryptamine: a second diuretic hormone in
Rhodnius prolixus. J. Exp. Biol.
156,557
-566.
Maddrell, S. H. P., O'Donnell, M. J. and Caffrey, R. (1993). The regulation of haemolymph potassium activity during initiation and maintenance of diuresis in fed Rhodnius prolixus. J. Exp. Biol. 177,273 -285.[Abstract]
Martini, S. V., Goldenberg, R. C., Fortes, F. S., Campos-de-Carvalho, A. C., Falkenstein, D. and Morales, M. M. (2004). Rhodnius prolixus Malpighian tubule's aquaporin expression is modulated by 5-hydroxytryptamine. Arch. Insect Biochem. Physiol. 57,133 -141.[CrossRef][Medline]
Montoreano, R., Triana, F., Abate, T. and Rangal-Aldao, R. (1990). Cyclic AMP in the Malpighian tubule fluid and in the urine of Rhodnius prolixus. Gen. Comp. Endocrinol. 77,136 -142.[CrossRef][Medline]
O'Donnell, M. J. and Maddrell, S. H. P. (1984).
Secretion by the Malpighian tubules of Rhodnius prolixus Stal:
electrical events. J. Exp. Biol.
110,275
-290.
O'Donnell, M. J., Rheault, M. R., Davies, S. A., Rosay, P., Harvey, B. J., Maddrell, S. H. P., Kaiser, K. and Dow, J. A. T. (1998). Hormonally controlled chloride movement across Drosophila tubules is via ion channels in stellate cells. Am. J. Physiol. 274,R1039 -R1049.[Medline]
Plawner, L., Pannabecker, T. L., Laufer, S., Baustian, M. D. and Beyenbach, K. W. (1991). Control of diuresis in the yellow fever mosquito Aedes aegypti: evidence for similar mechanisms in the male and female. J. Insect Physiol. 37,119 -128.[CrossRef]
Rheault, M. R. and O'Donnell, M. J. (2001).
Analysis of epithelial K+ transport in Malpighian tubules of
Drosophila melanogaster: evidence for spatial and temporal
heterogeneity. J. Exp. Biol.
204,2289
-2299.
Rheault, M. R. and O'Donnell, M. J. (2004).
Organic cation transport by Malpighian tubules of Drosophila
melanogaster: application of two novel electrophysiological methods.
J. Exp. Biol. 207,2173
-2184.
Te Brugge, V. A. and Orchard, I. (2002). Evidence for CRF-like and kinin-like peptides as neurohormones in the blood-feeding bug Rhodnius prolixus. Peptides 23,1967 -1979.[CrossRef][Medline]
Te Brugge, V. A., Miksys, S. M., Coast, G. M., Schooley, D. A. and Orchard, I. (1999). The distribution of a CRF-like diuretic peptide in the blood feeding bug Rhodnius prolixus. J. Exp. Biol. 202,2017 -2027.[Abstract]
Te Brugge, V. A., Schooley, D. A. and Orchard, I. (2002). The biological activity of diuretic factors in Rhodnius prolixus. Peptides 26,671 -681.
Te Brugge, V. A., Lombardi, V. C., Schooley, D. A. and Orchard, I. (2005). Presence and activity of a Dippu-DH31-like peptide in the blood-feeding bug, Rhodnius prolixus. Peptides 26,29 -42.[CrossRef][Medline]
Te Brugge, V. A., Schooley, D. A. and Orchard, I. (in press). Sequence and biological activity of the Rhodnius prolixus DH31 neuropeptide. J. Exp. Biol.
CiteULike 
Complore 
Connotea 
Del.icio.us 
Digg 
Reddit 
Technorati 
Twitter What's this?
This article has been cited by other articles:
|
|
 |
|
  G. M. Coast Neuroendocrine control of ionic homeostasis in blood-sucking insects J. Exp. Biol., February 1, 2009; 212(3): 378 - 386. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
S. Maddrell Insect homeostasis: past and future J. Exp. Biol., February 1, 2009; 212(3): 446 - 451. [Abstract] [Full Text] [PDF]
|
|
| |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
